DE1808717C3 - Receiver for frequency, phase or amplitude modulated vibrations with a crash barrier - Google Patents

Description

the noise-controlled crash barrier, namely the blocking of the low-frequency amplifier when Distortion products reduced to a very small value

The object on which the invention is based is to provide a further safety device for the crash barrier according to the main patent compared to distortion products, especially with an even lower input voltage achieve.

This problem is solved in that the additional noise barrier that responds to the noise little!? ns two selective circles tuned to frequencies outside the signal frequency range has that these frequencies and the bandwidths of the circles are selected such that harmonics at least of the high signal frequencies do not fall simultaneously in the pass band of all circuits, and that Switching means are included that only emit a DC output voltage that can be used in the crash barrier, if approximately the same voltage can be tapped on all selective circles.

According to the invention, a technique is used to achieve the object, as described in a similar manner in selective call technology is common. There, too, several frequencies are used as a call criterion in order to achieve a To prevent the selective call device from responding by means of a voice frequency.

Since the amplitudes of higher-order harmonics, as is well known, are already quite clear, the harmonics of the low signal frequencies (e.g. 300-600 Hz) do not interfere with the squelch with himself. It is therefore sufficient to choose the resonance frequencies of the circles in such a way that the harmonics are higher Signal frequencies (e.g. above 100 Hz) do not fall within the bandwidth of the circles. In addition to the location of the The bandwidth also plays a role in this measurement, because the narrower the bandwidth, the more narrow-band it is Circles are, the deeper you get with the signal frequency, the harmonics of which are still at Dimensioning can be taken into account. With this dimensioning, the question of effort plays a role for the circles essential role. For the sake of simplicity, two selective ones are used in the crash barrier according to the invention Provide circles, but the security against the false response of the crash barrier due to distortion products the more selective circles with different resonance frequencies, the more the signal frequencies are increased be used.

As already indicated above, the crash barrier according to the main patent could be small Input voltages of the receiver, i.e. where the control of the response of the crash barrier from Noise is taken over, if distortion products of the signal frequencies occur, it still increases

ίο an undesired response of the squelch come. This effect is eliminated by the invention.

In the simplest case, according to the invention, in the frequency-selective element 25 of FIG. 1 instead of the one circuit, two selective circuits (resonance frequencies, for example in the order of 9 and 11 kHz) are provided, which are controlled by the amplifier. The voltages that can be tapped off at these selective circuits are rectified separately and then fed to a circuit in which the two DC voltages are e.g. B. be added. Only when both circuits supply an output voltage, i.e. when noise occurs, will the circuit shown in FIG. 2 of the left-hand part of the curve 30, ie only in this case can the combined squelch be made to respond in a controlled manner by the noise-separated part. Since the frequencies of the two selective circuits are chosen so that the harmonics of at least the higher frequencies of the signal band do not cause a substantial voltage to arise in both circuits at the same time, a usable DC voltage is only emitted when noise arrives at the discriminator output.
An amplifier with a downstream rectifier can also be used to generate the DC voltage of the noise-controlled squelch, the amplifier having the two selective circuits in the negative feedback branch in the form of filters that are permeable at the resonance frequencies.

A usable DC voltage only arises here if it is fed to the amplifier Voltage from the discriminator output voltages of both frequencies are included. Due to the Dimensioning of the circles this only occurs in the case of noise.

1 sheet of drawings

Claims (1)

Claim: Receiver for frequency-, phase- or amplitude-modulated oscillations with the field strength independent output voltage and a crash barrier, in which either the control voltage of the receiver or the rectified carrier voltage if it exceeds a threshold for Control of the low-frequency part is used, and in the case of the for the control of the Low-frequency part of the voltage used, a voltage derived from the noise is switched in the opposite direction is, with a known crash barrier to gain this tension is provided which is one of the magnitude of the noise in an outside of the signal frequency range emits the frequency range-dependent DC voltage, with an addition stage is provided in the two opposing DC voltages a fixed DC voltage is added and finally the voltage sum via an adjustment element is performed, the setting of the voltage sum used to control the low-frequency part and thus the setting of the response threshold of the crash barrier allows, characterized according to patent 1282 746, that the additional noise-responsive crash barrier at least two on frequencies outside the signaling frequency range has matched selective circles that these frequencies and the bandwidths of the circles are chosen such that harmonics of at least the high frequencies of the Signal frequency range does not fall simultaneously within the bandwidth of all circuits and that switching means are included that only emit a compensating voltage that can be used in the crash barrier if approximately the same voltage can be tapped on all selective circles. The invention relates to a receiver for frequency-, phase- or amplitude-modulated oscillations output voltage independent of the field strength and a crash barrier in which either the control voltage of the receiver or the rectified carrier voltage if it exceeds a threshold, is used to control the low-frequency part, and in which the for the control of the low-frequency part voltage used is counteracted with a voltage derived from noise, where To gain this voltage, a known crash barrier is also provided, which is one of the Size of the noise in a frequency range outside the signal frequency range dependent Outputs DC voltage, an addition stage is also provided in which to the two opposing DC voltages a fixed DC voltage is added and finally the voltage sum is performed via an adjusting element that controls the setting of the Low frequency part used voltage sum and thus the setting of the response threshold of the Crash barrier allowed according to patent 12 82 746. The object on which the invention of the main patent is based is, for a recipient to create a crash barrier whose response threshold can be varied within wide limits. The crash barrier according to the main patent will be explained with reference to FIG. The intermediate frequency amplifier of the receiver is denoted by 3, the discriminator by 2 and the low frequency amplifier by 3. In front a voltage is taken from the limiter in the intermediate frequency amplifier, which via a Amplifier 23 is fed to a rectifier 24. ίο At the output of this rectifier you get a Voltage that depends on the input signal In addition to this voltage derived from the carrier, the Krachsperre according to the main patent still a voltage derived from the noise. That's why the Discriminator output connected to an amplifier and a frequency-selective element 25. The pass band of the frequency-selective element is above the utilized signal frequency range. The one from this one Noise voltage passed through to the frequency-selective element is rectified in the rectifier 26. the Rectifiers 24 and 26 are designed so that their output voltages have opposite signs. At the same time there is a fixed DC voltage to the two voltages with opposite voltages Sign added. The total voltage is fed to the setting regulator 28 via an isolating stage 27, the output voltage of which is fed to the switching stage 29. The to the output voltages of the rectifier 24 and 26 added fixed DC voltage can also be used if the following steps are appropriately designed be zero. In Figure 2 of the drawing, the course is the Total voltage from the voltage rectified in rectifiers 24 and 26 and the fixed DC voltage as a function of the input voltage of the receiver and denoted by 30. This The total voltage is made up of the fixed DC voltage 31, which is added to this, via resistors divided output voltage 32 of the rectifier 24 and the negative sign added, but also divided down output voltage 33 of the rectifier 26 together. One recognizes from the Representation of the F i g. 2 that the setting threshold can now be selected anywhere between 0.1 and 3 μV. The course of the distortion products 34 and the voltage course 35 caused by spark interference is also shown in FIG. The effects of these interfering components play a role here practically no longer a role. Strong extraneous interference occurs in the squelch according to the invention, as is the case with federal railway overhead lines etc. occur, then some of the energy of these disturbances also falls into the receiver passband and a carrier is simulated, which unlocks the LF part via the carrier-controlled squelch part want. Interference of this type also includes a low-frequency interference spectrum, that of noise is comparable. This is why a noise-controlled squelch would die when such interference occurs Initiate blocking and only unblocking again when the useful carrier has grown so much that the Setting the preselected signal-to-noise ratio is exceeded again. Accordingly, he wants The noise-controlled squelch portion of Fig. 1 initiates the lockout. The smoke barrier is in the range from 0.5 to 3 μV according to the main patent controlled mainly by the carrier. So there are the disadvantages in this area